Print control apparatus and method for printing images on a continuous sheet

ABSTRACT

A print control apparatus and method for determining a sheet size specified by a first print job and a sheet size specified by a second print job, deciding on a sheet width usable by the first print job and a sheet width usable by the second print job based on determined respective sheet sizes, deciding on a sheet width of a continuous sheet to be used by the first print job and the second print job based on the decided respective sheet widths, and printing an image based on the first print job and an image based on the second print job on a continuous sheet supplied from a sheet supplying unit that supplies a continuous sheet having the decided sheet width.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a Continuation of U.S. patent applicationSer. No. 12/960,417 filed Dec. 3, 2010, which claims priority fromJapanese Patent Application No. 2010-041658 filed Feb. 26, 2010, each ofwhich is hereby incorporated by reference herein in their entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to print control and, moreparticularly, to print control apparatuses and methods for printingimages on a continuous sheet, such as roll paper.

2. Description of the Related Art

Hitherto, when images are printed on a continuous sheet such as rollpaper, after printing based on one job has been performed, thecontinuous sheet is cut, and the remaining continuous sheet is rewound.When the next printing job is to be performed, the rewound continuoussheet is conveyed to a printing position again and printing is performed(refer to Japanese Patent Laid-Open No. 2003-211754).

In the case in which such a procedure is used to perform printing,whenever a print job is received for which a sheet of a size differentfrom the prior one is to be used, it is necessary to cut and exchangethe sheet, causing the time for completing a plurality of jobs to becomelong.

SUMMARY OF THE INVENTION

An aspect of the present invention provides an apparatus and method forprint control in which the above-described problem has been solved.Another aspect of the present invention provides an apparatus and methodfor print control that realize efficient execution of a plurality ofprint jobs that specify different sheet sizes when printing is performedon a continuous sheet.

Further features of the present invention will become apparent from thefollowing description of exemplary embodiments with reference to theattached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a schematic configuration of an image formingapparatus which is an exemplary embodiment of the present invention.

FIG. 2 is a block diagram illustrating a configuration related to thecontrol of the image forming apparatus illustrated in FIG. 1.

FIGS. 3A to 3C illustrate exemplary print-waiting job lists according toan exemplary embodiment of the present invention.

FIG. 4 is a flowchart illustrating a flow of processing according to anexemplary embodiment of the present invention.

FIG. 5 is a flowchart illustrating a flow of reception processing for aprint job according to an exemplary embodiment of the present invention.

FIG. 6 is a flowchart illustrating a flow of image processing for aprint job according to an exemplary embodiment of the present invention.

FIG. 7 is a flowchart illustrating a flow of printing processing for aprint job according to an exemplary embodiment of the present invention.

FIGS. 8A to 8C illustrate exemplary display screens presented to a useraccording to an exemplary embodiment of the present invention.

FIGS. 9A to 9C illustrate exemplary presentations of print-waiting joblists according to an exemplary embodiment of the present invention.

FIG. 10 is a flowchart illustrating a flow of processing for executingprint jobs in accordance with a pattern specified by a user according toan exemplary embodiment of the present invention.

FIGS. 11A and 11B illustrate recommended patterns according to anexemplary embodiment of the present invention.

DESCRIPTION OF THE EMBODIMENTS

Hereinafter, embodiments of the present invention are described withreference to the attached drawings. Note that the relative arrangementof the components of apparatuses and the shapes of the apparatuses inthe embodiments are only examples, and the embodiments are not limitedto these examples.

FIG. 1 illustrates a schematic configuration of an image formingapparatus, which is an example of a print control apparatus in thepresent embodiment. The image forming apparatus illustrated in FIG. 1 isan example that includes only a print function which prints datareceived from an external apparatus, but not limited to this, the imageforming apparatus may be an apparatus functioning as a copier that alsoincludes a reading unit for reading images of documents or may be anapparatus functioning as a multifunctional apparatus that includesadditional functions.

Description is made of an example in which a roll sheet is used as arecording material (medium on which to record or recording sheet). Thisroll sheet is an example of a continuous sheet, but a continuous sheetother than a rolled one may also be used. Regarding cutting of acontinuous sheet, the continuous sheet may be automatically cut by theimage forming apparatus or may be cut in accordance with an instructiongiven by a user. The types of recording material that can be used arenot limited to paper but may be various materials on which recording canbe performed. In addition, the image forming apparatus may be anapparatus that can print an image not only on a continuous sheet butalso on a cut sheet which has been cut in a predetermined size inadvance.

The printing method is not limited to inkjet image printing using imageprinting liquid ink described later. Solid ink may be used as arecording agent applied to a recording material. Various methods may beused such as electrophotographic printing using toner, dye sublimationprinting, thermal transfer printing, and dot impact printing. Inaddition, monochrome recording using only a black color (including grayscale) may be used, not limited to color recording using a plurality ofrecording agents. Further, not limited to visible images, invisible orhardly visible images may be printed. Not limited to general images,printed images may be wiring patterns, physical patterns for themanufacture of components, a base arrangement of DNA. In addition, thepresent embodiment can be applied to various types of recordingapparatus in which recording agents can be applied to recordingmaterials. Further, in the case in which the operation of the imageforming apparatus illustrated in FIG. 1 is controlled by instructionsfrom an externally connected apparatus, the external apparatus functionsas the print control apparatus.

FIG. 1 is a sectional view illustrating a schematic configuration of animage forming apparatus in which a roll sheet (continuous sheet longerthan a unit of printing (page) in a conveying direction) is used as arecording material. The image forming apparatus includes components 101to 115 described below, which are arranged in a casing. However, thesecomponents may be divided and arranged in a plurality of casings.

A control unit 108 houses a control section that includes a controller(including a central processing unit (CPU), a micro-processing unit(MPU), and/or the like), an output unit (display or sound informationgenerator) for outputting user interface information, and variousinput/output (I/O) interfaces, and performs various types of control ofthe whole image forming apparatus.

Two sheet cassettes, i.e., an upper sheet cassette 101 a and lower sheetcassette 101 b are provided as units for holding and supplying a rollsheet (also called sheet supplying units). A user mounts a roll sheet(hereinafter called a sheet) in the image forming apparatus afterputting the sheet in a magazine. A sheet drawn out of the upper sheetcassette 101 a and a sheet drawn out of the lower sheet cassette 101 bare respectively conveyed in a direction a and a direction b in thefigure. The sheet from either of the cassettes is conveyed in adirection c and reaches a conveyer unit 102. The conveyer unit 102conveys the sheet in a direction d (horizontal direction) using aplurality of rotating rollers 104 during print processing. When thesheet cassette supplying the sheet is changed from the current one tothe other one, the already drawn out sheet is rewound into the cassette,and a sheet to be newly supplied is supplied from a cassette in whichthe sheet is set. Note that the present image forming apparatus allowsroll sheets having widths of 5 inches, 6 inches, 8 inches, and 12 inchesto be set in the cassettes 101 a and 101 b.

A head unit 105 is arranged above the conveyer unit 102 in such a manneras to face the conveyer unit 102. The head unit 105 holds independentprint heads 106 corresponding to a plurality of colors (seven colors inthe present embodiment) arranged along the sheet conveying direction.The present embodiment includes seven print heads, corresponding to cyan(C), magenta (M), yellow (Y), light cyan (LC), light magenta (LM), gray(G), and black (K). Of course, colors other than these colors may beused, and it is not necessary to use all of these colors together.

In the image forming apparatus, an image is formed on a sheet byejecting ink from the print heads 106 in synchronization with themovement of the sheet conveyed by the conveyer unit 102. Note that theprint heads 106 are arranged such that positions to which ink is ejecteddo not overlap the rotating rollers 104. Instead of directly ejectingink to the sheet, ink may be first applied to an intermediate medium andthen to the sheet, to form an image. The conveyer unit 102, the headunit 105, and the print heads 106 form a unit for printing of thepresent embodiment.

Ink tanks 109 independently store ink having respective colors. The inkis supplied from the ink tanks, through tubes, 109 to sub tanks providedfor respective colors, from where the ink is supplied to the print heads106 through tubes.

Regarding the print heads 106, line heads having respective colors(seven colors in the present embodiment) are arranged along theconveying direction d at the time of printing. Each line head may beformed of a single seamless nozzle chip, or may be a head in whichseparate nozzle chips are regularly arranged in a line or staggeredarray. The head used in the present embodiment has a full multi-headstructure which has nozzles arranged so as to cover the full width ofthe printed range of a sheet which has the maximum allowable size in thepresent apparatus. In inkjet printing in which ink is ejected fromnozzles, a method using thermal devices, a method using piezoelectricdevices, a method using electrostatic devices, a method using MEMSdevices, and the like may be employed. The timing of ejecting ink fromeach nozzle in accordance with print data is determined by an outputsignal from a conveyance encoder 103.

After an image has been formed on a sheet, the sheet is conveyed fromthe conveyer unit 102 to a scanner unit 107. In the scanner unit 107, itis determined whether or not a printed image has a problem, and thestates of the apparatus including the state of ink injection is checked,by optically reading the printed image or a special pattern on thesheet. Example methods of checking the printed image include a method ofchecking the ink ejection state by reading a pattern for checking thestate of the heads, or a method of determining whether or not theprinting has been performed successfully by comparing the printed imagewith the original image. The method of checking or determination can beappropriately selected from various methods.

The sheet is conveyed from the vicinity of the scanner unit 107, in adirection e, into a cutter unit 110. In the cutter unit 110, the sheetis cut in units of predetermined unit lengths of printing. Thepredetermined unit length of printing changes in accordance with thesize of a printed image. For example, the length in the conveyingdirection is 135 mm for an L-size photograph and 297 mm for A4 size. Thecutter unit 110 cuts the sheet in units of pages for simplex printing,but may not cut the sheet in units of pages, depending on the content ofa print job. In the case of duplex printing, the cutter unit 110 doesnot cut the sheet after printing on the first surface (surface on whichimages are printed first, i.e., front surface, for example) in units ofpages, and images are continued to be printed up to a predeterminedlength, and after images have been printed on the second surface(surface on which images are printed later, i.e., back surface, forexample), the cutter unit 110 cuts the sheet in units of pages. Notethat the cutter unit 110 does not necessarily cut the sheet for everyimage page in simplex printing or in printing on the back surface induplex printing. Without cutting the sheet before the sheet is conveyeda predetermined distance, the sheet may be cut after the sheet has beenconveyed the predetermined distance, and a separate cutter apparatus maycut the sheet into units of image pages in accordance with aninstruction given through a manual operation, for example. Regarding thewidth of the sheet, when the sheet needs to be cut in the widthdirection thereof, a separate cutter apparatus is used to cut the sheet.

The sheets conveyed from the cutter unit 110 are conveyed in a directionf in the figure to a back-surface information printing unit 111. Theback-surface information printing unit 111 prints predeterminedinformation on the back surface of the sheet in the case in which animage is printed only on one surface of the sheet. Examples ofinformation printed on the back surface of the sheet include information(order management number, for example) such as characters, symbols,codes corresponding to each printed image. In the case in which theprint heads 106 print images corresponding to a print job for duplexprinting, the back-surface information printing unit 111 prints theinformation described above in an area other than the area that includesimages printed by the print heads 106. The back-surface informationprinting unit 111 may employ a method of affixing a recording agent,thermal transfer printing, or inkjet printing.

The sheets that passed through the back-surface information printingunit 111 are conveyed to a dryer unit 112. The dryer unit 112 appliesheat to the sheets passing therethrough in a direction g in the figureusing warm air (heated gas (air)) to dry the ink applied sheets in ashort time. Note that exemplary various methods which can be employedfor drying the sheets other than that using warm air include cold air,heating with a heater, air drying through simply leaving the sheets tostand, irradiation with electromagnetic waves such as ultraviolet light.The sheets cut in units of unit lengths of printing pass through thedryer unit 112 one by one, and are conveyed in a direction h in thefigure to a sorting unit 114.

The sorting unit 114, which has a plurality of trays (18 trays in thepresent embodiment), selects trays to which the sheets are discharged inaccordance with the unit lengths of printing. Each tray has a traynumber assigned thereto. The sorting unit 114 discharges the sheetspassing therethrough in a direction i in the figure into a traycorresponding to the tray number set for each printed image, whilechecking the state of the tray so as to determine whether or not thetray is vacant or full of sheets, using a sensor provided on each of thetrays. The tray to which the cut sheet is to be discharged may be a trayspecified by the source (host apparatus) that issued the print job or avacant tray that is appropriately specified by the image formingapparatus side. A predetermined number of sheets can be discharged toone tray. In the case of a print job that prints more than thispredetermined number of sheets, the sheets are discharged to a pluralityof the trays. The number, size, and kind of sheets that can bedischarged to a tray change in accordance with the size (type) or thelike of the tray. In FIG. 1, both large sheets (larger than the L size,such as A4 size) and small sheets (L size) can be discharged to a groupof trays (hereinafter called large trays) arranged vertically (up-downdirection). Small sheets (L size) can be discharged to a group of trays(hereinafter called small trays) arranged horizontally (left-rightdirection), but large sheets cannot be discharged to the small trays.The number of output sheets which can be discharged to the large traysis larger than that of the small trays.

States such as “sheets are being discharged” and “discharging completed”are displayed using display devices (LEDs, for example), therebyallowing a user to know the states. For instance, by providing aplurality of LEDs emitting different colors for each tray, a user can benotified of the various states of each tray in accordance with the colorof an illuminating LED or whether the LED is illuminating or blinking.Priority levels may be assigned to respective trays, whereby the imageforming apparatus, for execution of print jobs, allocates vacant trays(with no sheets) in descending order of the priority levels, as trays towhich sheets are to be discharged. In a default configuration, an uppertray has a higher priority level among the large trays, and a traycloser to the left side has a higher priority among the small trays. Thesmall trays have higher priority levels than the large trays. Thepriority levels may be set such that trays at locations easilyaccessible by the user have high priority levels. The priority levelsmay be appropriately changed by a user operation.

A sheet winding unit 113 winds a sheet whose front surface has imagesprinted thereon and which has not been cut in units of pages. In thecase of duplex printing, a sheet having images formed first on the frontsurface thereof, is not cut in units of pages by the cutter unit 110,and after the continuous printing on the front surface has beenfinished, the sheet is cut. The sheet having images printed on the frontsurface thereof, passes through the units in a direction j in thefigure, and wound by the sheet winding unit 113. The wound sheet, withimages having been formed on a sequence of pages thereof, is conveyedagain through the unit in a direction k in the figure such that the backsurface, which is opposite the previous front surface, is set as asurface on which printing can be performed, that is, the surface thatfaces the print heads 106 has been reversed. At this time, the sheetwinding unit 113 is rotated in a direction opposite to that at the timeof winding, whereby the sheet is conveyed with the cut edge at thefront. By conveying the sheet in this manner, images for the backsurface, opposite the front surface, of the sheet are printed. In thecase of usual simplex printing, the sheets on which images have beenprinted are conveyed to the sorting unit 114 without being wound by thesheet winding unit 113.

Since the sheet is wound using the sheet winding unit 113 and printingis performed on the back surface by reversing the sheet in the case ofduplex printing, as described above, the surface of the sheet at thedischarging of the sheet to the sorting unit 114 is reversed in the caseof duplex printing compared with the case of simplex printing. In otherwords, in the case of simplex printing, since the sheet is not reversedusing the sheet winding unit 113, the sheet on which the image of thefirst page is printed is discharged in a state in which the image of thefirst page is facing downward. In the case in which a print job prints aplurality of pages, the sheet of the first page is first discharged to atray, and then, subsequent pages are discharged sequentially and piledup. Such discharging is called face down discharging. On the other hand,in the case of duplex printing, since the sheet is reversed using thesheet winding unit 113, the sheet on which the image of the first pageis printed is discharged in a state in which the image of the first pageis facing upward. In the case in which a print job prints a plurality ofpages, the sheet including the last page is first discharged to a tray,and then, sheets of pages are discharged sequentially in reverse orderand piled up, and finally, the sheet having the image of the first pageprinted thereon is discharged. Such discharging is called face updischarging. Note that the order in which the first surface is printed(descending order or ascending order) may be changed in accordance withsimplex printing or duplex printing to make the respective surfaces ofthe sheets, at the time of discharging, in simplex printing and duplexprinting the same (always face up or face down).

An operation unit 115 allows a user to perform various operations and tobe notified of various kinds of information. The operation unit 115includes hardware keys and a touch panel allowing a user to performvarious operations and a display for notifying the user of various kindsof information. Presentation of information to a user may be performedby outputting sounds (such as a buzzer and voice) based on soundinformation generated by a sound generator. The operation unit 115allows a user to check the state of printing corresponding to each ordernumber, indicating, for example, which tray holds a sheet having theuser-specified image printed thereon or whether the image is beingprinted or has been printed. In addition, the operation unit 115 allowsa user to check the various states of the apparatus, such as ink levelsand the remaining amounts of sheet, and to instruct the apparatus toperform maintenance, such as head cleaning, through operation of theoperation unit 115. Further, the size (roll width), length, and type(quality or material of a sheet, such as plain paper, glossy paper,coated paper, or a film) of the sheet set in each of the sheet cassettes101 a and 101 b can be registered in an internal memory through theoperation unit 115.

FIG. 2 is a block diagram for illustrating a configuration related tothe control of the image forming apparatus illustrated in FIG. 1. Animage forming apparatus 200 is the image forming apparatus illustratedin FIG. 1. The configuration described below is only an example, andvarious modifications are possible.

The control unit 108 mainly includes a main control unit 201, an imageprocessing unit 207, a scanner control unit 208, an engine control unit209, a motor control unit 210, a head control unit 211, and a sortercontrol unit 212 illustrated in FIG. 2. These components can communicatewith one another via a system bus 214.

The main control unit 201 includes a central processing unit (CPU) 202,a read-only memory (ROM) 203, a random access memory (RAM) 204, anexternal interface (I/F) 205, and a hard disk drive (HDD) 206. Thesecomponents can communicate with one another via a system bus 213. Themain control unit 201 controls the entire image forming apparatus 200.

The CPU 202 is a microprocessor (microcomputer) based central processingunit, controls the operation of the whole image forming apparatus 200 byexecuting programs and activating hardware. The ROM 203 stores theprograms executed by the CPU 202 and fixed data necessary for variousoperations of the image forming apparatus 200. The RAM 204 is used bythe CPU 202 as a work area and a temporary storage area for variousreceived data, and to store various setting data. The external I/F 205is used to connect external apparatuses to the image forming apparatus200. The external I/F 205 may by a local I/F or a network I/F. Theexternal I/F 205 may provide wired connection or wireless connection.The HDD 206 stores and reads programs executed by the CPU 202, printdata, setting information necessary for the various operations of theimage forming apparatus 200. Note that the HDD 206 may be replaced withanother large capacity storage apparatus.

The image processing unit 207 performs various kinds of image processingincluding development (conversion) of print data (data and image filesrepresented by a page description language, for example) processed bythe image forming apparatus 200 into image data (bitmap image). Theimage processing unit 207 also converts a color space (YCbCr, forexample) included in input print data to a standard RGB color space(sRGB, for example). In addition, the image processing unit 207 performsvarious kinds of image processing for the image data, such as imageresolution conversion to an appropriate number of pixels allowed by theprint processing performed by the image forming apparatus 200, imageanalysis, and image correction as required. The image data obtained bythe image processing described above is stored in an internal RAM, theRAM 204, or the HDD 206. Note that, similarly to the main control unit201, the image processing unit 207 also includes a CPU, a ROM, and a RAMconnected to one another via a system bus, and the CPU performs theabove-described image processing, in accordance with programs stored inthe ROM.

The scanner control unit 208, by controlling an image sensor inaccordance with control commands received from the CPU 202 or the like,reads an image on a sheet, obtains analog brightness data for red (R),green (G), and blue (B) colors, and converts the data to digital data.Examples of the image sensor which can be employed include a CCD imagesensor and a CMOS image sensor. The image sensor may be a linear imagesensor or an area image sensor. The scanner control unit 208 instructsdriving of the image sensor, obtains the state of the image sensor whichhas been driven, analyzes brightness data obtained by the image sensor,and detects no ejection of ink from the print heads 106 or the cuttingpositions of a sheet. A sheet which has been determined by the scannercontrol unit 208 to have an image correctly printed thereon isdischarged to a specified tray of the sorting unit 114, after beingsubjected to drying processing of the ink on the sheet. Note that,similarly to the main control unit 201, the scanner control unit 208also includes a CPU, a ROM, and a RAM connected to one another via asystem bus, and the CPU performs the image capturing processingdescribed above, in accordance with programs stored in the ROM.

The engine control unit 209 controls the processing for printing animage, based on print data, on a sheet in accordance with controlcommands received from the CPU 202 or the like. The engine control unit209, at the time of printing processing, controls the head control unit211, the motor control unit 210, the scanner control unit 208, and thesorter control unit 212, whereby a series of printing processing isperformed. In other words, under the control of the engine control unit209, ink is applied to a sheet using the print heads 106, sheets areconveyed, it is determined whether or not printing has been successfulby using the image sensor, and sorting is performed using the trays ofthe sorting unit 114. Control commands, various data, status signals,and the like are received from and sent to the main control unit 201through the system bus 214. Note that, similarly to the main controlunit 201, the engine control unit 209 also includes a CPU, a ROM, and aRAM connected to one another via a system bus, and the CPU controls theabove-described printing processing, in accordance with programs storedin the ROM.

The motor control unit 210 instructs driving of a drawing roller fordrawing a sheet out of the cassette and driving of a conveying rollerfor conveying the drawn out sheet, and controls the motors for drivingthe rollers in accordance with control commands received from the enginecontrol unit 209. By obtaining information about the state of therotation of the conveying rollers and the like, the motor control unit210 makes a sheet be conveyed at an appropriate speed along anappropriate path or stop, and measures a length by which the sheet hasbeen conveyed. Note that, similarly to the main control unit 201, themotor control unit 210 also includes a CPU, a ROM, and a RAM connectedto one another via a system bus, and the CPU performs theabove-described processing related to motor control, in accordance withprograms stored in the ROM.

The head control unit 211 instructs the print heads 106 for respectivecolors to eject ink and sets ejection timings for adjusting thepositions of dots on a recording material (ink applied positions), andperforms adjustment and the like by obtaining information about thestates of the heads being driven. In accordance with control commandsreceived from the engine control unit 209, the head control unit 211controls driving of the print heads 106 in accordance with print data,makes the print heads 106 eject ink, and thereby makes an image beformed on a sheet. Note that, similarly to the main control unit 201,the head control unit 211 also includes a CPU, a ROM, and a RAMconnected to one another via a system bus, and the CPU controls theabove-described processing using the print heads 106, in accordance withprograms stored in the ROM.

The sorter control unit 212 controls instruction regarding a conveyingpath of a sheet, switching of a tray, and the like, in accordance withcontrol commands received from the engine control unit 209 to dischargesheets to the trays of the sorting unit 114. In addition, the sortercontrol unit 212 can detect whether or not a sheet exists on each trayon the basis of the output from the sheet detection sensor of each tray.Note that, similarly to the main control unit 201, the sorter controlunit 212 also includes a CPU, a ROM, and a RAM connected to one anothervia a system bus, and the CPU controls the above-described processingusing the sorting unit 114, in accordance with programs stored in theROM.

A host apparatus 215, which corresponds to the external apparatusdescribed above, is externally connected to the image forming apparatus200. The host apparatus 215 is a supply source of image data for makingthe image forming apparatus 200 perform printing, and issues orders forvarious print jobs.

The host apparatus 215 may be realized by a general purpose personalcomputer (PC) or by other types of data supplying apparatus, such as animage capturing apparatus, which captures images and generates imagedata. Such image capturing apparatuses include, for example, a reader(scanner) that scans images on a document and generates image data and afilm scanner that scans a negative film or positive film and generatesimage data. Other examples include a digital camera that shoots a stillimage and generates digital image data, and a digital video camera thatpicks up a movie and generates movie data. Further, by providing a photostorage system in the network or by providing a memory slot forinserting a removable memory device to the image forming apparatus,image files stored in the photo storage system or the removable memorydevice may be read and printed, through generation of image data. Inaddition, instead of a general purpose PC, various types of data supplyapparatus such as a special purpose terminal for the image formingapparatus may be used. Such a data supply apparatus may be a componentof the image forming apparatus or may be externally connected to theimage forming apparatus. In the case in which the host apparatus 215 isa PC, the operating system (OS), application software for generatingimage data, and the printer driver for the image forming apparatus 200are installed in the memory of the PC. The printer driver controls theimage forming apparatus 200 and generates print data by converting imagedata provided by an application software program to the data form thatcan be processed by the image forming apparatus 200. Print data may beconverted to image data on the host apparatus 215 side and provided tothe image forming apparatus 200. Note that all of the processingdescribed above need not be implemented in software, and part or thewhole of the processing may be implemented in hardware, such asapplication specific integrated circuits (ASICs). Image data providedfrom the host apparatus 215, commands, status signals, and the like canbe transmitted to or received from the image forming apparatus 200through the external I/F 205.

In the examples described above, it has been assumed that the functionalblocks include respective CPUs. However, not limited to this, aconfiguration is possible in which some of the functional blocks, whichdo not include respective CPUs, operate under the control of the maincontrol unit 201 and/or the engine control unit 209. Further, each ofthe functional blocks illustrated in FIG. 2 may be divided intoappropriate processing units or control units or may be combined,differently from the current functional divisions, thereby allowingvarious configurations to be used. Note that a direct memory accesscontroller (DMAC) may also be used to read data from a memory.

The flow of processing performed by the image forming apparatus 200 toexecute a print job will now be described. The image forming apparatus200, when receiving a print job, creates a print-waiting job list, asillustrated in FIGS. 3A to 3B, in the HDD 206. A print job includesinformation about an output sheet size indicating the size of a sheetsubsequent to cutting of the sheet, a sheet type indicating the qualityof the sheet, a printing mode (simplex printing, duplex printing,bookbinding printing, etc.) in addition to print data (file).

Job numbers in order of reception (i.e., job numbers in accordance withthe order in which jobs are received) are assigned to respective printjobs registered in the print-waiting job list. Also when the externalI/F 205 is a network I/F and print jobs are received from a plurality ofhost apparatuses that exist in the network, job numbers in order ofreception are assigned. For each of the print jobs, an output sheet size(width×length (inch)), a sheet type, and a file name (specified by auser who issued the job) for identifying print data, specified by thereceived print job, are recorded. As job control information, rollwidths for which printing is possible (printable roll widths) aredecided upon on the basis of the output sheet size specified by a printjob, and the decided roll widths are recorded. When a roll width to beactually used is decided upon from among the printable roll widths, theroll width is recorded as a print roll width. Further, the status ofeach print job is recorded, and updated whenever it changes.

In the example illustrated in FIG. 3A, for example, the record for thefirst print job shows that, the output sheet size is “4 inches×6inches”, the sheet type is “A”, and the file name of print data is“xxx.jpg”. It is also shown that the decided printable roll width is “6inches”, “6 inches” has been set as the print roll width, and “printprocessing is being performed” for the job by the engine control unit209. The record for the second job shows that there are two of theprintable roll widths, “6 inches” and “8 inches”, “6 inches” has beenset as the print roll width, and “image processing is being performed”for the job by the image processing unit 207. The record for the thirdjob shows that the job is in a state of having been received by the maincontrol unit 201, and the print roll width has not yet been decided.

FIG. 4 is a flowchart illustrating a flow of processing performed by theimage forming apparatus 200 when a print job is received and executed.The flowchart illustrates the flow of processing performed by therespective CPUs of the functional blocks illustrated in FIG. 2 as aresult of the CPUs loading control programs stored in the ROMs or theHDD 206 into the RAMs and executing the programs. Overall control of thewhole processing is performed by the CPU 202. It is assumed that thesize (roll width) and type of the sheet set in each of the cassettes 101a and 101 b have been registered in the RAM 204 or the RAM of the enginecontrol unit 209 through operation of the operation unit 115 by a user.

In step S401, when a print job is received through the external I/F 205,the CPU 202 starts processing for this print job. The received print jobis first stored in the HDD 206, and various settings for executing theprint job are set.

FIG. 5 is a flowchart illustrating the details of the processing of stepS401. This flowchart illustrates the flow of processing that the CPU 202performs by loading control programs stored in the ROM 203 or the HDD206 into the RAM 204 and executing the programs.

When the print job is received in step S501, the job is stored in theHDD 206. In step S502, information about the output sheet size includedin the received job (specified by the print job) is read and the longlength (long side length) and the short length (short side length) amongthe width and length (horizontal and vertical) are obtained. The sheetsize may be determined on the basis of the sheet size stored in theprint job as is, or may be determined on the basis of calculationthrough the measurement of the size of print data in the print job.

Then in step S503, a printable roll width is decided upon. Here, it isfirst determined whether or not each of the short side length and longside length obtained in step S502 can be used in the image formingapparatus 200. When it is determined that the length can be used, thelength determined to be usable is made to be a printable roll width.

The image forming apparatus 200 allows a roll sheet having a widthlarger than the long side length or the short side length to be used forprinting. Hence, a length that is different from the long side lengthand short side length may be made to be a printable roll width. To dothis, information about whether or not printing on a sheet having awidth larger than that of the output sheet is “permitted” or “notpermitted” is registered in the RAM 204 in advance through operation ofthe operation unit 115. In the case in which “permitted” has beenregistered, a width, which is allowed to be used in the image formingapparatus 200, larger than the width of the output sheet is also made tobe a printable roll width. Here, a “larger width” is a length in thewidth direction at the time of printing an image, and refers to a widthlarger than the length in the width direction of the output sheet, atthe time of printing the image, which may be the width or length of theoutput sheet. In other words, through rotating processing of the image,a length in the longitudinal direction of the output sheet may becomethe length in the width direction.

In addition, in the case in which “permitted” has been registered, itmay be further determined whether or not the larger width is made to bea printable roll width in accordance with the print mode of the printjob. In the case in which bookbinding printing is specified as the printmode, the image forming apparatus 200 performs printing with the pageorder in accordance with the content of bookbinding printing, butbookbinding such as pasting itself is not performed. Hence, in the casein which bookbinding has been specified, after the image formingapparatus 200 has discharged sheets to be bound into a book, the sheetsare bound into a book by a bookbinding machine provided separately fromthe image forming apparatus 200. The sheets are cut in this bookbindingmachine. Accordingly, in the case in which “permitted” has beenregistered and the printing mode is bookbinding, a width larger thanthat of the output sheet is added as one of the printable roll widths.This makes an object printed on a sheet having a width larger than thatof the output sheet be an object to be bound into a book later,resulting in higher efficiency. However, by providing a bookbindingfunction within the image forming apparatus 200, the image formingapparatus 200 may be made to automatically perform bookbindingprocessing, such as sheet width/length cutting and pasting.

When a width larger than that of the output sheet is selected as theprintable roll width, a width which makes a smaller margin may beselected in accordance with the amount of a margin. Here, a margin inthe width direction may be determined on the basis of a differencebetween the width of the output sheet and a roll width, and a margingenerated at the trailing end of a roll sheet may be determined on thebasis of a difference between images and the remaining amount of theroll sheet by arranging the images in various patterns (horizontally andvertically).

In step S504, the printable roll width decided upon as described aboveis registered (stored in the RAM 204) as a printable roll width of thereceived print job in the print-waiting job list. When a plurality ofthe printable roll widths have been registered in the manner describedabove, priority levels may be assigned to them. A higher priority levelis assigned to a printable roll width closer to the roll width set inthe image forming apparatus 200.

When the processing described above has been finished, the flow proceedsto step S402. However, since subsequent print jobs are received insuccession, the processing of FIG. 5 is repeated in parallel for eachjob, whenever a print job is received.

In step S402, the received print job is processed by the imageprocessing unit 207 so as to have a form for which the engine controlunit 209 performs printing processing.

FIG. 6 is a flowchart illustrating the detailed processing of step S402.This flowchart illustrates the flow of processing that the CPU of theimage processing unit 207 performs by loading control programs stored inthe ROM of the image processing unit 207 or the HDD 206 into the RAM ofthe image processing unit 207 and executing the programs.

In step S601, the Nth print job in the print-waiting job list is readfrom the HDD 206 and written into the RAM of the image processing unit207. Then, the printable roll widths of unprocessed print jobs stored inthe HDD 206 are read from the print-waiting job list stored in the RAM204 and written into the RAM of the image processing unit 207. “N” is avariable which is changed in accordance with a print job to beprocessed. Here, assuming that a print job is received for the firsttime in a state in which there have been no unprocessed print jobs, thefirst job is taken out.

In step S602, it is determined whether or not the print roll width ofthe prior ((N−1)th) print job is included in the printable roll widthsof the Nth print job. Here, the (N−1)th print job may be a job for whichprinting processing is already being performed. Regarding the (N−1)thprint job, it has already been decided which one among the printableroll widths is to be used as the width of a sheet, i.e., the print rollwidth. When the determination result of step S602 is affirmative, theflow proceeds to step S605, and when the determination result of stepS602 is negative, the flow proceeds to step S603. The flow proceeds tostep S603 also when there does not exist the (N−1)th print job.

In step S603, by comparing the printable roll widths of the next((N+1)th) print job with those of the Nth print job, it is determinedwhether or not the same printable roll width is included in them. When aplurality of the same ones are included in them, one of them is selectedin accordance with priority levels. The priority levels in descendingorder are as follows: (1) the width of the roll sheet currently set inthe cassette 101 a or 101 b, (2) the width equal to that of the printsheet size of the Nth print job, (3) the width allowing a margin to beminimized. A sheet that meets the condition of a high priority level ispreferentially selected as a sheet to be used. Regarding (1), one of thecassettes 101 a and 101 b which has already been selected for printprocessing may be made to have a higher priority level. Regarding (2),when the printable roll widths include a width larger than that of theoutput sheet and a width equal to that of the output sheet, the widthequal to that of the output sheet is preferentially selected. Regarding(3), this is taken into consideration when there are a plurality ofwidths larger than the width of the output sheet. Here, when thedetermination result of step S603 is affirmative, the flow proceeds tostep S605, and when the determination result is negative, the flowproceeds to step S604. The flow proceeds to step S604 also when the(N+1)th print job does not exist.

In step S604, one of the printable roll widths of the Nth print job isselected. When there is a single printable roll width, this one isselected, and when there is more than one, one of them is selected inaccordance with priority levels. The priority levels are similar to (1)to (3) described above.

In step S605, it is decided that the printable roll width selected inone of steps S602 to S604 is made to be the printable roll width of theNth print job, and is set (stored) in the RAM of the image processingunit 207.

Then in step S606, image processing for the Nth job is performed inaccordance with the printable roll width which has been set in stepS605. Specifically, the print data is converted to data (developed intoimage data) having a form that allows printing processing to beperformed. At this time, the length and width of the output sheet maychange places, depending on the print roll width which has been set. Inthis case, processing for rotating an image by 90 or 270 degrees is alsoperformed. In addition, when the set roll width is larger than the widthof the output sheet, processing for adding margins is also performed. Inthe processing for adding margins, white image data may be added or thestarting position of the image may be controlled so as to make marginsbe provided. Further, when the margins are added, marks or linesindicating cutting positions are also added. At this time, the image isnot reduced or enlarged, and is printed as an image having the(original) size specified by the print job.

The processing described above is repeated, while 1 is added to N instep S608, until it is determined in step S607 that the processingdescribed above has been performed for all the print jobs for whichprinting is to be performed.

FIG. 3B illustrates an example in which a print roll width has beendecided upon in the case in which it has been set that printing is “notpermitted” on a sheet having a width larger than that of an outputsheet. The printable roll width is limited to the long side length orshort side length of the output sheet among the roll widths which aresupported by the image forming apparatus 200. In the first print job,since the printable roll widths of a subsequent print job does notinclude “12 inches”, and since a roll sheet with a width of 12 incheshas been set in the cassette 101 a or 101 b, the print roll width hasbeen set to be “12 inches”. In the second print job, since the printableroll widths of a subsequent print job includes “6 inches”, the printableroll width has been set to be “6 inches” among “6 inches” and “8inches”. Further, in step S606, processing for rotating the images ofthe first and third print jobs by 90 or 270 degrees is performed.

FIG. 3C illustrates an example in which a print roll width has beendecided upon in the case in which it is set that printing is “permitted”on a sheet having a width larger than that of an output sheet. Theprintable roll width is equal to or larger than the width of the outputsheet among the roll widths which are supported by the image formingapparatus 200. By comparing the printable roll widths of prior andsubsequent print jobs, the print roll widths have been set to be “12inches”, which is common among the print jobs. Here, since the secondand third jobs specify bookbinding, printable roll widths larger thanthe widths of the output sheets have been added. In step S606, 90 or 270degree image rotation processing is performed for the first print job.For the second and third print jobs, rotation processing may or may notbe performed in accordance with the number of pages. Further, for thesecond and third print jobs, since printing is performed on a sheet witha width larger than those of the output sheets, margin data and cuttinglines corresponding to the positions of the output sheets are added.

In the second (N=2) processing or later, since the print roll width ofthe immediately prior print job has been decided upon in the priorprocessing, in steps S602 and S603, it is determined whether or not aprint roll width equal to that of the immediately prior print job isincluded.

In some cases, the processing described above is not repeated untilprocessing for all the jobs on the print-waiting job list has beenfinished. In the case in which a job that specifies duplex printing isincluded, when image data (data supplied to the engine control unit 209)of a predetermined length has been generated, with a sheet length as areference, control exits the flow for a time. After exiting the flow, byinitializing the value of N (making N=1), processing regardingunprocessed print jobs is started from step S601. This is to preventdischarging of sheets of the first print job from being delayed,because, in duplex printing, a plurality of images are continuouslyprinted on the first surface before printing on the other surface, and asheet is not cut image by image at the time of printing on the firstsurface.

In the processing described above, although the print roll width for theNth job is decided upon by referring to only the immediately prior printjob and immediately subsequent print job, print jobs two or more apartfrom the present print job may be further referred to.

Further, in the processing described above, when a print job has printdata corresponding to not only one sheet but a plurality of pages interms of output sheets, processing similar to the above-describedprocessing is performed for images (pages) neighboring one another onthe same surface of a sheet. In addition, although the examples in whichthe sheet sizes of respective print jobs are compared have beendescribed, the types of sheet are also compared, whereby printing isperformed such that the same type of sheet continues.

After exiting the flow illustrated in FIG. 6, control proceeds to stepS403, where the image data generated by the processing illustrated inFIG. 6 is supplied to the engine control unit 209 and printingprocessing is performed.

FIG. 7 is a flowchart illustrating the details of the processing of stepS403. This flowchart illustrates the flow of processing that the CPU ofthe engine control unit 209 performs by loading control programs storedin the ROM of the engine control unit 209 or the HDD 206 into the RAM ofthe engine control unit 209 and executing the programs.

In step S701, a print job (image data) which has been converted to aform for which printing is possible is read from the RAM of the imageprocessing unit 207 and written into the RAM of the engine control unit209. In step S702, by comparing the print roll width of this print jobwith that of the immediately prior print job or that of an alreadyselected sheet cassette, it is determined whether or not roll sheetswitching or exchanging is necessary. Here, when the compared widths aredifferent from each other, it is determined that roll sheet switching orexchanging is necessary. Even when the compared widths are the same, itis determined that roll sheet switching or exchanging is necessary whenthe remaining amount of the roll sheet is insufficient. When it isdetermined that roll sheet switching or exchanging is necessary, theflow proceeds to step S703, and when it is determined that roll sheetswitching or exchanging is not necessary, the flow proceeds to stepS704.

In step S703, when the roll sheet to be used for the present print jobhas been set in one of the cassettes 101 a and 101 b which has not beenselected, the cassette supplying a roll sheet is switched to the otherone. When the roll sheet to be used for the present print job has notbeen set in the cassette 101 a or 101 b, a user needs to exchange thecurrent roll sheet for another one or newly set another one. Hence, amessage prompting roll sheet switching or exchanging, together with thesize of a roll sheet (roll width), is displayed on the display of theoperation unit 115. The host apparatus 215 may be similarly notified ofthe message prompting roll sheet switching or exchanging together withthe roll width. When roll sheet setting for the cassette 101 a or 101 bhas been performed by a user in accordance with the message ornotification, the flow proceeds to step S704.

When it has been determined in step S702 that roll sheet switching orexchanging is not necessary or when roll sheet switching or exchanginghas been performed in step S703, printing for the print job to beprocessed is performed in step S704. Specifically, the engine controlunit 209 makes a sheet be supplied from the cassette 101 a or 101 b inaccordance with the size of an image to be printed and a type of sheetto be used. The engine control unit 209 makes the conveyer unit 102convey the sheet to the printing position of the head unit 105, performsprinting of images based on the image data on the first surface of thesheet successively, and makes the sheet be conveyed to the readingposition of the scanner unit 107. It is determined whether or not theimages are correctly printed on the basis of the content of the imagedata obtained through reading of the printed images by the scanner unit107, and the sheet is conveyed to the cutter unit 110. When duplexprinting jobs are included, the sheet is not cut in units of pages bythe cutter unit 110, and the sheet, in the form of a continuous sheet,is made to pass through the dryer unit 112, where it is subjected to anink drying process. Then the sheet is made to be wound by the sheetwinding unit 113. When printing of all the images to be arranged on thefirst surface is finished, the sheet is cut by the cutter unit 110,printing is similarly performed for images to be arranged on theopposite surface of the sheet, which has been reversed and conveyedagain from the sheet winding unit 113. At the time of printing images onthe opposite surface, the sheet is cut in units of pages by the cutterunit 110. Note that when duplex printing jobs are included, afterprinting on only the first surface has been finished for one print job,printing on the first surface for the subsequent print job is performed,and then printing on the opposite surface is performed. On the otherhand, in the case of simplex printing, after the printing on the firstsurface has been finished, the sheet is cut in units of pages by thecutter unit 110, without being wound by the sheet winding unit 113.

In step S705, printed sheets cut in units of pages (in units of outputsheets) by the cutter unit 110 are sequentially discharged to specifiedtrays of the sorting unit 114.

In step S706, printing and discharging of sheets are repeated until itis determined that printing of all the pages in a print job to beprinted has been finished, and when printing and discharging of pages tobe printed has been finished, the flow proceeds to step S707. In stepS707, it is determined whether or not there remains a print job yet tobe processed, and when it is determined that there remains a print jobyet to be processed, the flow goes back to step S701, where processingfor the next print job is performed.

Note that in the printing processing described above, when printing iscontinued on the same sheet, the sheet is not rewound to the cassette101 a or 101 b or drawn out again.

As described above, according to the present embodiment, even when printjobs that include printing with different sizes and orientationscontinue, printing is performed on the same sheet, which realizesefficient processing of a plurality of print jobs. In addition,regarding sheet supplying cassettes, an already selected cassette ispreferentially used. In other words, the frequency of roll sheetswitching or exchanging can be decreased. At this time, printing on asheet with a width larger than that of the output sheet is permitted ornot in accordance with print modes, and is permitted for the case inwhich cutting processing is performed by a bookbinding apparatus later,whereby work efficiency is maintained. Further, since print jobs areexecuted in the order in which they have been received, the print jobscan be easily managed to make a plurality of functional blocks share theprocessing. In other words, print jobs can be executed without complexprocessing for switching between the print jobs.

As described above, it is efficient to continuously perform printing fora plurality of print jobs. On the other hand, when the image formingapparatus 200 automatically determines sheets to be used in print jobsor the order in which printing is performed in accordance withpredetermined rules, a result not expected by a user may arise. Forexample, a user may have various kinds of requirements, such ascontinuously performing as many print jobs as possible and using aspecific sheet first. Hence, examples of deciding how print jobs are tobe executed in accordance with instructions from a user are describedbelow.

FIG. 8A illustrates an exemplary selection screen for allowing a user toselect how a plurality of print jobs are to be executed. This inquiryscreen is displayed on the display of the operation unit 115 or the hostapparatus 215 in a state in which the image forming apparatus 200 hasaccepted a plurality of print jobs and is waiting for the execution ofthe print jobs. The message in this screen allows a user to selectwhether the method of executing the print jobs is to be automaticallydecided upon in accordance with the rules set in advance in the imageforming apparatus 200 or to be decided upon by the user. The method ofexecuting the print jobs includes a method of deciding upon the sheet tobe used.

When “Yes” is selected in the screen illustrated in FIG. 8A, a pluralityof print jobs are executed in accordance with the predetermined rules bythe image forming apparatus 200, as described above with reference toFIGS. 4 to 7. In other words, the plurality of jobs are continuouslyexecuted using the same sheet as far as possible, including the case inwhich a sheet with a width larger than that of the output sheet. On theother hand, when “No” is selected, a user is made to specify thefollowing points in the determination of the method of executing thejobs.

When “No” is selected in the screen illustrated in FIG. 8A and aninstruction to display a selection screen for selecting recommendedcandidates is given, the screen is switched to the screen illustrated inFIG. 8B, where the user is made to select the priority of a sheet to beused. Here, a sheet corresponding to the pattern specified by the useramong the presented sheets, is preferentially used. In the screenillustrated in FIG. 8B, since the printable roll widths (and sheet type)of the upper print jobs (print jobs to be executed earlier) of a groupof jobs (FIG. 9A) currently waiting for printing are “6 inches (A)” and“8 inches (A)”, these two are displayed as recommended candidates. Notethat FIG. 9A is similar to FIG. 3A. FIG. 9A can be displayed on thedisplay of the operation unit 115 or the host apparatus 215 inaccordance with an instruction or the like from the user. Referring toFIG. 9A, if a “6-inch (A)” sheet is used, the print jobs Nos. 1 to 3, 5,7, and 8 in the group of print jobs currently waiting for printing canbe continuously and hence efficiently executed. On the other hand, when“8-inch (A)” is specified due to reasons such as “An 8-inch (A) sheethas already been drawn out”, “The amount of sheet to be conveyed ispreferably as small as possible”, and “Print jobs that use an 8-inch (A)sheet are preferably finished first”, the print jobs Nos. 2, 6, and 8are continuously executed. Note that the above-described two patternsillustrate the upper two patterns, in the group of print-waiting printjobs, which allow more print jobs to be continuously executed. However,three or more of the recommended patterns may be listed, or, by showingonly one pattern, the user may be asked whether or not the pattern is tobe used for the execution of print jobs. Further, only the patternscorresponding to the sheets currently set in the cassettes of the imageforming apparatus 200 may be displayed.

When “pattern 1” is selected in the screen illustrated in FIG. 8B, thescreen illustrated in FIG. 9B, which allows print jobs that can use theroll width “6 inches” and uses the sheet type “A” to be identified, isdisplayed on the display of the operation unit 115 or the host apparatus215. The screen illustrated in FIG. 9B also displays information aboutwhich of the width and length of the output sheet is selected as theprint roll width. By looking at this screen, the user can give aninstruction to remove a specific print job from the group of print jobsto be continuously executed. In addition, since the screen illustratedin FIG. 9B displays calculated (estimated) printing time for each printjob, the user can refer to this information for the selection of themethod of executing the print job.

When “Pattern 2” is selected in the screen illustrated in FIG. 8B orwhen an instruction to display the next pattern is given in the screenillustrated in FIG. 9B, the screen illustrated in FIG. 9C is displayedon the display of the operation unit 115 or the host apparatus 215. Thescreen illustrated in FIG. 9C displays information similar to that ofthe screen illustrated in FIG. 9B, but by identifying appropriate printjobs using symbols different from those in FIG. 9B, it is made clearthat the screen illustrated in FIG. 9C displays a pattern different fromthat displayed by the screen illustrated in FIG. 9B. Note that the printjobs Nos. 2 and 8 in the group of print-waiting print jobs are commonfor both “Pattern 1” and “Pattern 2”. In addition, FIG. 9B and FIG. 9Cmay display respective information on the same job list. Also in thiscase, since different symbols (◯,Δ) are used for respective patterns,they are easily identified. Various symbols other than those used inFIGS. 9B and 9C may be used.

When printing is instructed (via the screen illustrated in FIG. 8B, 9B,or 9C, in some cases) after “No” has been selected in the screenillustrated in FIG. 8A, the screen illustrated in FIG. 8C is displayedon the display of the operation unit 115 or the host apparatus 215.

When “Pattern 1” is selected in FIG. 8C, printing is started in order ofpriority (in order of reception) for print jobs corresponding to pattern1. Here, printing is performed for the print jobs specified, in thescreen illustrated in FIG. 9B, as print jobs to be continuously printed.When “Pattern 2” is selected, similar operations are performed. In thecase in which a pattern has already been selected in FIG. 8B, forexample, printing may be performed without pattern selection in FIG. 8C.

Next, description is made of the flow of processing which is performedwhen “No” is selected in FIG. 8A and the above-described recommendedpatterns for continuously printing a plurality of print jobs are decidedupon, whereby printing is performed. FIG. 10 is a flowchart illustratingthe flow of processing in this case. This flowchart illustrates the flowof processing that the CPU of the engine control unit 209 performs byloading control programs stored in the ROM of the image processing unit207 or the HDD 206 in the RAM of the image processing unit 207 andexecuting the programs.

When “No” is selected in FIG. 8A and a plurality of print jobs have beeninput through the processing of step S401 illustrated in FIG. 4, theprintable roll widths of the print jobs listed in the print-waiting joblist are determined, in step S1001 illustrated in FIG. 10. Note that thejobs listed in the print-waiting job list may be a group of print jobswhich have been input within a given period of time, or may be a groupof print jobs, having a predetermined upper limit, which have waited apredetermined period of time for being input. Then, in step S1002, thesheet type of a sheet used by each of the group of the print jobs isdetermined.

In step S1003, when displaying of the print-waiting job list isinstructed through the operation unit 115, the print-waiting job listillustrated in FIG. 9A based on the information determined in stepsS1001 and S1002 is displayed on the display of the operation unit 115.Note that this processing of step S1003 may be skipped.

In step S1004, when displaying of recommended candidates is instructedthrough the operation unit 115, the recommended pattern selection screenillustrated in FIG. 8A is displayed on the display of the operation unit115. When it is determined in step S1005 that one of the recommendedpatterns displayed in this screen has been selected, the flow proceedsto step S1006, where the job list, illustrated in FIG. 9B or 9C, whichallows the selected recommended pattern to be identified is displayed onthe display of the operation unit 115.

In step S1007, when printing is instructed through the operation unit115, the screen illustrated in FIG. 8C is displayed, and when one of therecommended patterns is selected through the screen or when execution orprinting is instructed through the screen illustrated in FIG. 9B or 9C,the flow proceeds to step S1008.

In step S1008, image processing for the Nth (N=1) print jobcorresponding to the selected recommended pattern is performed, and theprocessing is repeated by incrementing N by 1 in step S1010 until it isdetermined in step S1009 that image processing for all the print jobsfor which printing is to be performed is finished. Note that all theprint jobs for which printing is to be performed are processed insequence such that print jobs corresponding to pattern 1 is firstprocessed and then unprocessed print jobs corresponding to pattern 2 areprocessed in sequence. The print jobs for which image processing hasbeen finished are subjected to the print processing of step S403illustrated in FIG. 4.

Note that in the case in which one of the plurality of recommendpatterns is selected by a user, as in FIGS. 8B and 8C, the user may beprovided with various kinds of information, thereby allowing the user toselect a pattern which is closer to the intention of the user.

FIG. 11A illustrates, for each recommended pattern, the number of printjobs for which printing can be continuously performed and the time whichis required to finish printing of all the print jobs when therecommended pattern has been selected (including print jobscorresponding to other patterns). This is displayed on the display ofthe operation unit 115 or the host apparatus 215 in response to aninstruction from the operation unit 115 or the host apparatus 215. Inthis case, it is assumed that more than three cassettes for holdingsheets are provided in the image forming apparatus 200, and a type Asheet having a roll width of 6 inches, a type A sheet having a rollwidth of 8 inches, and a type B sheet having a roll width of 6 inchesare set in the respective cassettes of the image forming apparatus 200.

In FIG. 11A, pattern 1 illustrates the case in which printing using atype A sheet having a width of 6 inches is performed first, and patterns2 and 3 illustrate the cases in which printing using a type A sheethaving a width of 8 inches and printing using a type B sheet having awidth of 6 inches are respectively performed first.

The recommendation (number of jobs) shows the number of print jobscontinuously executed first for each pattern. In other words, the screenillustrated in FIG. 11 a shows that six print jobs using a type A sheethaving a width of 6 inches continue in pattern 1, three print jobs usinga type A sheet having a width of 8 inches continue in pattern 2, and oneprint job using a type B sheet having a width of 6 inches is executed.Here, recommendation levels are determined on the basis of the numbersof jobs, and a numeral in front of the number of jobs represents arecommendation level assigned in accordance with descending order of thenumber of continuously executed jobs. A user can select a pattern on thebasis of the number of continuously executed jobs, by referring to therecommendation (number of jobs).

In FIG. 11A, recommendation (time) shows a total time needed to executeall the print jobs, for which printing is to be performed, for eachpattern which has been selected. Referring to FIG. 11B, the total timefor each pattern is the sum of printing times spent for printing onrespective sheets when print jobs are executed in sequence in accordancewith the pattern. Note that the total time includes the time required toswitch the sheet. In FIG. 11A, a numeral in front of the total timerepresents a recommendation level assigned in accordance with ascendingorder of the total time. A user can select a pattern on the basis of thetotal time, by referring to the recommendation (total time).

As described above, a user can start printing processing after selectingdesired options, by checking with a display screen the selection ofprint jobs to be subjected to continuous printing processing on the samesheet and the order in which printing is to be performed. At this time,the user need only select one of the plurality of prepared patterns forexecuting print jobs presented by the image forming apparatus 200,resulting in increased operability.

Further, there may be a case in which a user does not want a pluralityof print jobs to be continuously executed, for example, because the userwants to reduce the possibility of running out of the sheet during theexecution of a job, or the user wants to prevent printing, on the secondsurface, of prior jobs from being delayed owing to an error in asubsequent job, in the case of duplex printing. To deal with such cases,a capability may be provided which allows a user to specify theprohibition of continuous printing for a plurality of print jobs orspecify restriction on the number of jobs to be continuously processed.This may be realized by specifying through the operation unit 115 whenthe screen illustrated in FIG. 8A is displayed, or may be set in theimage forming apparatus 200 in advance.

In the above description, by realizing processing except for printing,such as decision on printable roll widths and print roll widths,rotation, and addition of margins, using an external apparatus such as ahost apparatus or an external controller, the image forming apparatusmay be made to perform printing in accordance with the externalapparatus. In this case, the external apparatus can obtain statusinformation (current printing status, information about sheet cassettes,etc.) from the image forming apparatus, and thereby perform theabove-described processing. The external apparatus can specify how printjobs are to be continuously performed, and in what order printing is tobe performed. In this case, the external apparatus functions as a printcontrol apparatus.

The present invention is also realized by performing the followingprocessing. That is, the present invention is realized by providing asystem or an apparatus with software (programs) that realizes thefunctions of the above-described embodiments, by means of a network orvarious storage media, and as a result of the computer (or a processor,such as a CPU, an MPU, and/or the like) of the system or the apparatusreading and executing the programs. The programs may be executed by asingle computer or a plurality of computers cooperating with oneanother. In addition, it is not necessary that the above-describedprocessing is realized using only software, and part or the whole of theprocessing may be realized using hardware.

The present invention is not limited to the above-described embodiments,and various modifications (including application to other embodimentsand combination with other embodiments) are possible.

While the present invention has been described with reference toexemplary embodiments, it is to be understood that the invention is notlimited to the disclosed exemplary embodiments. The scope of thefollowing claims is to be accorded the broadest interpretation so as toencompass all such modifications and equivalent structures andfunctions.

What is claimed is:
 1. An apparatus comprising: a determination unitconfigured to determine an output sheet size specified by a first printjob and an output sheet size specified by a second print job; a decisionunit configured to decide on a sheet width of a continuous sheet to beused by the first print job and the second print job based on each ofthe determined output sheet size specified by the first print job andthe determined output sheet size specified by the second print job; anda control unit configured to cause a printing unit to print an imagebased on the first print job and an image based on the second print jobcontinuously on a continuous sheet having the sheet width decided on bythe decision unit.
 2. The apparatus according to claim 1, wherein thedetermination unit determines a long side length and a short side lengthspecified by the first print job and a long side length and a short sidelength specified by the second print job; wherein the decision unitdecides on the sheet width of the continuous sheet to be used based oneach of the determined long side length and short side length of thefirst print job and the determined long side length and short sidelength of the second print job; and wherein the control unit is able torotate, in accordance with the sheet width decided on by the decisionunit, at least one image based on the first print job and the imagebased on the second print job.
 3. The apparatus according to claim 2,wherein, in a case where the long side length of the first print job isequal to the short side length of the second print job or in a casewhere the short side length of the first print job is equal to the longside length of the second print job, the decision unit is able to decidean equal sheet width as the sheet width of the continuous sheet to beused, and the control unit causes the printing unit to print the imagebased on the first print job and the image based on the second print jobonto the continuous sheet having the sheet width decided on by thedecision unit by rotating at least one of the image based on the firstprint job and the image based on the second print job.
 4. The apparatusaccording to claim 1, wherein, in a case where a sheet width equal tothe output sheet size determined by the determination unit and a sheetwidth larger than the output sheet size determined by the determinationunit are able to be used for the first print job and the second printjob, the decision unit decides on the sheet width of the continuoussheet to be used by giving priority to the sheet width equal to theoutput sheet size determined by the determination unit.
 5. The apparatusaccording to claim 1, wherein the decision unit is able to decide, asthe sheet width of the continuous sheet to be used, the sheet sizehaving the sheet width larger than at least one of the output sheet sizeof the first print job and the output sheet size of the second printjob.
 6. The apparatus according to claim 1, wherein, in a case where atleast one of sheet sizes of a continuous sheet which is able to besupplied to the printing unit is larger than the output sheet sizedetermined by the determination unit, the decision unit regards theoutput sheet size determined by the determination unit and the at leastone of sheet sizes which is able to be supplied to the printing unit andis larger than the output sheet size determined by the determinationunit as a sheet size being able to be used and decides on the sheetwidth of the continuous sheet to be used.
 7. The apparatus according toclaim 1, wherein, in a case where the sheet width decided by thedecision unit is larger than at least one of the determined output sheetsize specified by the first print job and the determined output sheetsize specified by the second print job, the control unit controls theprinting unit to perform the continuous printing after performingprocessing of adding a margin to the image based on the first print jobor to the image based on the second print job.
 8. The apparatusaccording to claim 1, wherein, in a case where a plurality of sheetwidths is able to be decided as the sheet width being able to be usedfor the first print job and as the sheet width being able to be used forthe second print job, the decision unit decides on the sheet width ofthe continuous sheet to be used by giving priority to a sheet size of acontinuous sheet set to a sheet supplying unit.
 9. The apparatusaccording to claim 1, wherein the control unit causes the printing unitto execute each of print jobs in order of reception.
 10. The apparatusaccording to claim 1, further comprising a presentation unit configuredto present, based on the sheet sizes determined by the determinationunit, a method of executing print jobs for which printing using a samecontinuous sheet is allowed to be performed, wherein the control unitperforms control such that images based on a plurality of the print jobsare continuously printed by the printing unit on the same continuoussheet supplied to the printing unit, in accordance with an instructionof a user based on the presentation made by the presentation unit. 11.The apparatus according to claim 10, wherein the presentation unitpresents a plurality of patterns as methods of executing the pluralityof the print jobs, and the print control unit performs control such thatprinting is performed by the printing unit in accordance with a patternspecified by a user.
 12. The apparatus according to claim 10, whereinthe presentation unit presents the plurality of the patternscorresponding to different orders in which printing is performed. 13.The apparatus according to claim 10, wherein the presentation unitpresents the plurality of the patterns corresponding to differentcontinuous sheets to be preferentially used.
 14. The apparatus accordingto claim 10, wherein the presentation unit presents the plurality of thepatterns corresponding to different times used to execute the pluralityof the print jobs.
 15. A method comprising: determining an output sheetsize specified by a first print job and an output sheet size specifiedby a second print job; deciding on a sheet width of a continuous sheetto be used by the first print job and the second print job based on eachof the determined output sheet size specified by the first print job andthe determined output sheet size specified by the second print job; andcausing a print unit to print an image based on the first print job andan image based on the second print job continuously on a continuoussheet having the decided sheet width.
 16. A storage medium storing aprogram for causing a computer to execute the method according to claim15.